Rotary type heat exchange apparatus with automatic flow rate exchange modulation

ABSTRACT

The present invention discloses that a rotary type heat exchange apparatus with automatic flow rate exchange modulation is installed with the tree or at least one kind of at least one temperature detecting device, at least one humidity detecting device and at least one gaseous or liquid state fluid composition detecting device at the position capable of detecting the temperature, humidity, and composition changes of the exchange fluid, wherein the detected signals are used as the references for modulating the pumping flow rate of exchange fluid, or for modulating the operating timing such as the rotating speed of the rotary type heat exchange rotating disk.

BACKGROUND OF THE INVENTION

(a) Field of the invention

The present invention improves the conventional rotary type double flowcircuit heat exchange apparatus to have the operating function ofautomatic exchange fluid flow rate modulation so as to timely change thetemperature distribution status between the fluid and the heat exchangerotating disk, or to modulate the composition ratio of the gaseous orliquid state pumping fluid, wherein the heat exchange rotating diskinside the rotary type heat exchange apparatus being insertinglyinstalled or coated with penetrating type or absorbing type moistureabsorbing material, or the heat exchange rotating disk itself having theconcurrent dehumidification function constitute the dehumidificationeffect of the total heat exchange function.

(b) Description of the Prior Art

The conventional double flow circuit heat reclaim device or total heatreclaim device for passing through by the gaseous or liquid statepumping fluid include:

(1) The fixed type fluid heat reclaim device;

(2) The fixed type fluid total heat reclaim device;

(3) The rotary type fluid heat reclaim device;

(4) The rotary type fluid total heat reclaim device.

Said heat reclaim devices are usually selected to operate at a set flowspeed, hence its heat exchange efficiency is affected by the temperaturedifference between input and output sides, or the fluid compositiondifference between the spaces of the exchange gaseous or liquid statefluids, or the difference of fluid speeds and the temperature differencebetween the spaces of the exchange gaseous or liquid state fluids;further, the conventional heat exchangers are unable to modulate theheat exchange flow rate so as to modulate the fluid compositiondifference between the spaces of the exchange gaseous or liquid statefluids, as well as have the automatic modulation function to proactivelymodulate the heat exchange flow rate thereby achieving energy savingeffect by matching with the temperature difference or humiditydifference.

SUMMARY OF THE INVENTION

The present invention discloses that the conventional rotary type doubleflow circuit heat exchange apparatus is made to have the operatingfunction of the rotary type heat exchange apparatus having automaticexchange fluid flow rate modulation, and through the modulation of therotary type heat exchange rotating disk or rotary type total heatexchange rotating disk driven by the rotating disk driving devicethereby modulating the flow rate, temperature distribution, humiditydistribution, and gaseous or liquid state compositions of the exchangefluid.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view showing the operating principles of theconventional rotary type total heat exchange apparatus.

FIG. 2 is a schematic view of the conventional rotary type total heatexchange apparatus having two fluid streams in different flow directionsto pass through different positions of the rotary type total heatexchange rotating disk.

FIG. 3 is the block schematic view of the embodiment showing the presentinvention is capable of automatically operatively controlling the flowrate of heat exchange fluid.

FIG. 4 is a block schematic view of the embodiment showing that thepresent invention is further installed with the temperature detectingdevice to operatively control the flow rates of the heat exchangefluids.

FIG. 5 is a block schematic view of the embodiment showing that thepresent invention is further installed with the temperature detectingdevice and humidity detecting device to operatively control the flowrates of the total heat exchange fluids.

FIG. 6 is a schematic view of the structural principle of the embodimentshowing that the present invention is further installed with temperaturedetecting device and gaseous or liquid state composition detectingdevice to operatively control the flow rates of the heat exchangefluids.

FIG. 7 is a schematic view of the structural principle of the embodimentshowing that the present invention is further installed with temperaturedetecting device, humidity detecting device and gaseous or liquid statecomposition detecting device to operatively control the flow rates ofthe total heat exchange fluids.

DESCRIPTION OF MAIN COMPONENT SYMBOLS

-   11: Temperature detecting device-   21: Humidity detecting device-   31: Gaseous or liquid state fluid composition detecting device-   100: Rotary type heat exchange rotating disk-   110: Rotating disk rotationally driving device-   111: Variable speed transmission device-   120 a, 120 b: Unidirectional fluid pump-   123: Double flow circuit fluid pumping device-   130: Heater-   200: Rotary type total heat exchange rotating disk-   300: Power source-   250: Operative control device-   1000: Rotary type heat exchange apparatus-   a, b, c, d: Fluid port

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The warming energy reclaim effectiveness of the conventional rotary typeheat exchange apparatus or rotary type total heat exchange apparatus hasvery wide range of applications, and the more representative rotary typetotal heat exchange apparatus is taken as the example herein, such asthat FIG. 1 is a schematic view showing the operating principles of theconventional rotary type total heat exchange apparatus; as shown in FIG.1, the conventional rotary type total heat exchange apparatus usuallyinstalled with two fluid pumping devices in different flow directionsand four fluid ports for pumping the two fluid streams of temperaturedifference in different flow directions through the two sides of therotary type total heat exchange rotating disk (200) inside theconventional total heat exchange apparatus, wherein the two fluidstreams are respectively pumped in through the two fluid ports atdifferent sides and are respectively discharged through the fluid portat the other side, so as the two fluid circuits are segregated to passthrough the rotationally driven rotary type total heat exchange rotatingdisk (200) at different positions, such as that FIG. 2 is a schematicview of the conventional rotary type total heat exchange apparatushaving two fluid streams in different flow directions to pass throughdifferent positions of the rotary type total heat exchange rotating disk(200); such as that by taking the example of the heat exchange apparatusfor indoor to outdoor air exchange in winter times, the indoor highertemperature air flow is pumped into the conventional rotary type totalheat exchange apparatus via the fluid port (a), and passes through thefluid circuit of the rotary type total heat exchange rotating disk (200)on one side, and then is discharged to the outside via the fluid port(b), and the lower temperature outdoor fresh air is pumped into theconventional rotary type total heat exchange apparatus via the fluidport (c) from the outside, passes through the fluid circuit of therotary type total heat exchange rotating disk (200) on the other side,and then is discharged into indoors via the fluid port (d), wherein thefluid port (a) and the fluid port (d) are disposed at the side passingto the inside, while the fluid port (c) and the fluid port (b) aredisposed at the side passing to the outside; in stable operation, oneside of the rotary type total heat exchange rotating disk (200) in theconventional rotary type total heat exchange apparatus between the fluidport (a) and the fluid port (b) forms the temperature distribution fromthe higher temperature at the fluid port (a) to gradually reduce to thelower temperature at the fluid port (b) and the other side of the rotarytype total heat exchange rotating disk (200) between the fluid port (c)and the fluid port (d) forms the temperature distribution from the lowertemperature at the fluid port (c) to gradually increased to the highertemperature at the fluid port (d), while the heat exchange efficiency isdecided by the fluid property, flow speed and characteristics of theheat exchange rotating disk in the heat exchange apparatus as well asthe temperature difference of the two side fluids; if the heat exchangerotating disk being insertingly installed or coated with penetratingtype, or absorbing type moisture absorbing material or the heat exchangerotating disk itself having the concurrent dehumidification function areapplied to constitute the total heat exchange rotating disk, then theabove said two fluid streams in different flow directions are formedwith the stable status of temperature difference and humidity saturationdifference at the two inlet/outlet ends and the two sides for passing bythe fluids in different flow directions of the rotary type total heatexchange rotating disk (200) inside the conventional rotary type totalheat exchange apparatus.

The present invention discloses that the conventional rotary type doubleflow circuit heat exchange apparatus is further made to have theoperating function of the rotary type heat exchange apparatus havingautomatic exchange fluid flow rate modulation thereby modulating theflow rate, temperature distribution, humidity distribution, and gaseousor liquid state compositions of the exchange fluid.

FIG. 3 is a block schematic view of the embodiment showing the presentinvention is capable of automatically operatively controlling the flowrate of heat exchange fluid;

As shown in FIG. 3, the present invention is mainly constituted by thatthe fluid port (b) and the fluid port (d) among the fluid port (a),fluid port (b), fluid port (c), and fluid port (d) of the double flowcircuit of the rotary type heat exchange apparatus (1000) arerespectively installed with the unidirectional fluid pumps (120 a)(120b) capable of producing negative pressure or positive pressure toconstitute the double flow circuit fluid pumping device (123), and it isthrough the power of power source (300) and operative control of theoperative control device (250) to drive the unidirectional fluid pumps(120 a)(120 b) of the double flow circuit fluid pumping device (123)being capable of producing negative pressure or positive pressure forpumping the two fluids to pass through the rotary type heat exchangerotating disk (100) in different areas and different flow directions,and the flow circuits of the two fluid streams are mutually isolated,wherein:

The rotary type heat exchange apparatus (1000) and the unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure can be integrally combined or separately installed toconstitute the double flow circuit fluid pumping device (123) function,and the two unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure are respectivelyinstalled to the fluid port (b) and the fluid port (d) so as to pump thefluid in different pumping flow directions; said two unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure are respectively driven by the electric motorindividually or are commonly driven by the same motor, wherein they areoperatively controlled by the operative control device (250) to operatein one or more than one functional modes of the following, including: 1)the two unidirectional fluid pumps (120 a)(120 b) are pumped in negativepressure for pumping the two fluid streams in different pumping flowdirections; 2) the two unidirectional fluid pumps (120 a)(120 b) arepumped in positive pressure for pumping the two fluid streams indifferent pumping flow directions; in said two functional modeoperations of said 1) & 2), the two fluid streams are pumped to passthrough different areas of the rotary type heat exchange rotating disk(100), the flow circuits of the two fluid streams are mutually isolated,and the flow directions of the two fluid streams are contrary to eachother;

The double flow circuit fluid pumping device (123): It is constituted byat least two unidirectional fluid pumps (120 a)(120 b), wherein thefluid port (b) and the fluid port (d) among the fluid port (a), fluidport (b), fluid port (c), and fluid port (d) of the double flow circuitinstalled within the rotary type heat exchange apparatus (1000) arerespectively installed with the unidirectional fluid pumps (120 a)(120b) being capable of producing negative or positive pressure toconstitute the double flow circuit fluid pumping device (123), therebyby the operative control device (250) to operative control the flow rateof the heat exchange fluid pumped by the double fluid circuit fluidpumping device (123) driven by the power source (300), as well as tooperative control the rotating speed of the rotary type heat exchangerotating disk (100) driven by the rotating disk rotationally drivingdevice (110);

The power source (300): It is the device including AC or DC city powersystem or independent power supply device to provide power source forthe operation of the rotary type heat exchange apparatus with automaticexchange flow rate modulation;

The operative control device (250): It is constituted byelectromechanical components, solid state electronic components, ormicroprocessors and related software and operative control interfaces tooperatively control the unidirectional fluid pumps (120 a)(120 b) of thedouble flow circuit fluid pumping device (123) by: 1) operativelycontrolling the switching functional operation; or 2) operativelycontrolling the flow rate of pumping heat exchange fluid; or 3)operatively controlling the temperature distribution status between thefluid and rotary type heat exchange rotating disk (100); or 4)operatively controlling the rotating speed of the rotary type heatexchange rotating disk (100) driven by the rotating disk rotationallydriving device (110); or 5) integrally operatively controlling at leasttwo of said items 1)2)3)4) in combination;

The rotating disk rotationally driving device (110): It is constitutedby electric motor or other rotational power source with variable speedtransmission device (111) for driving the rotary type heat exchangerotating disk (100) to rotate and modulating its rotating speed tochange its heat exchange characteristics;

The rotary type heat exchange rotating disk (100): It is rotationallydriven by the rotating disk rotationally driving device (110), whereinits disk is internally provided with two porous fluid circuit areas forpassing through different directional fluid flows and has the heatabsorbing or dissipating function, the two fluid circuits of the rotarytype heat exchange rotating disk are respectively provided with twofluid ports for respectively pumping two fluid streams, wherein thepassage of the two fluid streams are mutually isolated, thereby allowingthe fluids in different flowing directions to pass through the rotarytype heat exchange rotating disk (100) rotationally driven by therotating disk rotationally driving device (110) for heat exchangefunction operations;

The timings to operatively control the flow rate of heat exchange fluidand/or the rotating speed of rotary type heat exchange rotating disk(100) driven by rotating disk rotationally driving device (110) arethat: 1) the fluid flow rate and change timing are preset in the openloop operative control; or 2) it is randomly manually operativelycontrolled;

The unidirectional fluid pump (120 a) and unidirectional fluid pump (120b) can also be installed to the fluid ports (a)(d) or installed to thefluid ports (b)(c) in said embodiment of FIG. 3, wherein oneunidirectional fluid pump is pumped in positive pressure while the otherunidirectional fluid pump is pumped in negative pressure so as to allowthe two fluid streams to pass through the rotary type heat exchangerotating disk (100) in different pumping flow directions.

FIG. 4 is a block schematic view of the embodiment showing that thepresent invention is further installed with the temperature detectingdevice to operatively control the flow rates of the heat exchangefluids;

As shown in FIG. 4, the present invention is mainly constituted by thatthe fluid port (b) and fluid port (d) among the fluid port (a), fluidport (b), fluid port (c), and fluid port (d) of the double flow circuitof the rotary type heat exchange apparatus (1000) are respectivelyinstalled with the unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure to constitute thedouble flow circuit fluid pumping device (123), and it is through thepower of power source (300) and operative control of the operativecontrol device (250) to drive the unidirectional fluid pumps (120 a)(120b) of the double flow circuit fluid pumping device (123) being capableof producing negative pressure or positive pressure for pumping the twofluids to pass through the rotary type heat exchange rotating disk (100)in different areas and different flow directions, and the flow circuitsof the two fluid streams are mutually isolated, wherein:

The rotary type heat exchange apparatus (1000) and the unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure can be integrally combined or separately installed toconstitute the double flow circuit fluid pumping device (123) function,and the two unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure are respectivelyinstalled to the fluid port (b) and the fluid port (d) so as to pump thefluid in different pumping flow directions; said two unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure are respectively driven by the electric motorindividually or are commonly driven by the same motor, wherein they areoperatively controlled by the operative control device (250) to operatein one or more than one functional modes of the following, including: 1)the two unidirectional fluid pumps (120 a)(120 b) are pumped in negativepressure for pumping the two fluid streams in different pumping flowdirections; 2) the two unidirectional fluid pumps (120 a)(120 b) arepumped in positive pressure for pumping the two fluid streams indifferent pumping flow directions; in said two functional modeoperations of said 1) & 2), the two fluid streams are pumped to passthrough different areas of the rotary type heat exchange rotating disk(100), the flow circuits of the two fluid streams are mutually isolated,and the flow directions of the two fluid streams are contrary to eachother;

At least one temperature detecting device (11) is installed at theposition capable of directly or indirectly detecting the temperaturevariation of the pumping exchange fluid, wherein the detected signal isreferred as the operative control timing for the operative controldevice (250); including: 1) operatively controlling the flow rate of theexchange fluid pumped by the double flow circuit fluid pumping device(123); or 2) operatively controlling the rotating speed of the rotarytype heat exchange rotating disk (100) driven by the rotating diskrotationally driving device (110); or 3) operatively controlling saiditems 1) & 2) simultaneously;

The double flow circuit fluid pumping device (123): It is constituted byat least two unidirectional fluid pumps (120 a)(120 b), wherein thefluid port (b) and fluid port (d) among the fluid port (a), fluid port(b), fluid port (c), and fluid port (d) of the double flow circuitinstalled within the rotary type heat exchange apparatus (1000) arerespectively installed with the unidirectional fluid pumps (120 a)(120b) being capable of producing negative or positive pressure toconstitute the double flow circuit fluid pumping device (123), therebyby the operative control device (250) to operative control the flow rateof the heat exchange fluid pumped by the double fluid circuit fluidpumping device (123) driven by the power source (300), as well as tooperative control the rotating speed of the rotary type heat exchangerotating disk (100) driven by the rotating disk rotationally drivingdevice (110);

The power source (300): It is the device including AC or DC city powersystem or independent power supply device to provide power source forthe operation of the rotary type heat exchange apparatus with automaticexchange flow rate modulation;

The operative control device (250): It is constituted byelectromechanical components, solid state electronic components, ormicroprocessors and related software and operative control interfaces tooperatively control the unidirectional fluid pumps (120 a)(120 b) of thedouble flow circuit fluid pumping device (123) by: 1) operativelycontrolling the switching functional operation; or 2) operativelycontrolling the flow rate of pumping heat exchange fluid; or 3)operatively controlling the temperature distribution status between thefluid and the rotary type heat exchange rotating disk (100); or 4)operatively controlling the rotating speed of the rotary type heatexchange rotating disk (100) driven by the rotating disk rotationallydriving device (110); or 5) integrally operatively controlling at leasttwo of said items 1)2)3)4) in combination;

The rotating disk rotationally driving device (110): It is constitutedby electric motor or other rotational power source with variable speedtransmission device (111) for driving the rotary type heat exchangerotating disk (100) to rotate and modulating its rotating speed tochange its heat exchange characteristics;

The rotary type heat exchange rotating disk (100): It is rotationallydriven by the rotating disk rotationally driving device (110), whereinits disk is internally provided with two porous fluid circuit areas forpassing through different directional fluid flows and has the heatabsorbing or dissipating function, the two fluid circuits of the rotarytype heat exchange rotating disk are respectively provided with twofluid ports for respectively pumping two fluid streams, wherein the twofluid flow circuits are mutually isolated, thereby allowing the fluidsin different flowing directions to pass through the rotary type heatexchange rotating disk (100) rotationally driven by the rotating diskrotationally driving device (110) for heat exchange function operations;

The timings to operatively control the flow rate of heat exchange fluidand/or the rotating speed of rotary type heat exchange rotating disk(100) driven by rotating disk rotationally driving device (110) arethat: 1) the fluid flow rate and change timing are preset in the openloop operative control; or 2) it is randomly manually operativelycontrolled; or 3) to install at least one temperature detecting device(11) at the position capable of directly or indirectly detecting thetemperature variation, wherein the signals detected by the temperaturedetecting device (11) is referred to determine the operating timing foroperatively controlling the flow rate of pumping exchange fluid and/orthe rotating speed of the rotary type heat exchange rotating disk (100)driven by the rotating disk rotationally driving device (110);

The unidirectional fluid pump (120 a) and unidirectional fluid pump (120b) can also be installed to the fluid ports (a)(d) or installed to thefluid ports (b)(c) in said embodiment of FIG. 4, wherein oneunidirectional fluid pump is pumped in positive pressure while the otherunidirectional fluid pump is pumped in negative pressure so as to allowthe two fluid streams to pass through the rotary type heat exchangerotating disk (100) in different pumping flow directions.

FIG. 5 is a block schematic view of the embodiment showing that thepresent invention is further installed with the temperature detectingdevice and humidity detecting device to operatively control the flowrates of the total heat exchange fluid;

As shown in FIG. 5, the present invention is mainly constituted by thatthe fluid port (b) and fluid port (d) among the fluid port (a), fluidport (b), fluid port (c), and fluid port (d) of the double flow circuitof the rotary type heat exchange apparatus (1000) are respectivelyinstalled with the unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure to constitute thedouble flow circuit fluid pumping device (123), thereby by the operativecontrol device (250) to operative control the unidirectional fluid pumps(120 a)(120 b) capable of producing negative pressure or positivepressure of the double flow circuit fluid pumping device (123) beingdriven by the power source (300), wherein the pumping two fluid streamspass through the rotary type total heat exchange rotating disk (200) indifferent areas, and the flow directions of the two fluid streams aredifferent and mutually isolated, wherein:

The rotary type heat exchange apparatus (1000) and the unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure can be integrally combined or separately installed toconstitute the double flow circuit fluid pumping device (123) function,and the two unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure are respectivelyinstalled to the fluid port (b) and the fluid port (d) so as to pump thefluid in different pumping flow directions; said two unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure are respectively driven by the electric motorindividually or are commonly driven by the same motor, wherein they areoperatively controlled by the operative control device (250) to operatein one or more than one functional modes of the following, including: 1)the two unidirectional fluid pumps (120 a)(120 b) are pumped in negativepressure for pumping the two fluid streams in different pumping flowdirections; 2) the two unidirectional fluid pumps (120 a)(120 b) arepumped in positive pressure for pumping the two fluid streams indifferent pumping flow directions; in said two functional modeoperations of said 1) & 2), the two fluid streams are pumped to passthrough different areas of the rotary type total heat exchange rotatingdisk (200), the flow circuits of the two fluid streams are mutuallyisolated, and the flow directions of the two fluid streams are contraryto each other;

At least one temperature detecting device (11) and at least one humiditydetecting device (21) are installed at the positions capable of directlyor indirectly detecting the temperature and humidity variations of thepumping exchange fluid, including installing both or at least onedetecting device, wherein the detected signals are referred as theoperating timing for the operative control device (250); including: 1)operatively controlling the flow rate of the exchange fluid pumped bythe double flow circuit fluid pumping device (123); or 2) operativelycontrolling the rotating speed of the rotary type total heat exchangerotating disk (200) driven by rotating disk rotationally driving device(110); or 3) operatively controlling said items 1) & 2) simultaneously;

Said temperature detecting device (11) and humidity detecting device(21) are integrally combined or individually separately installed;

The double flow circuit fluid pumping device (123): It is constituted byat least two unidirectional fluid pumps (120 a)(120 b), wherein thefluid port (b) and fluid port (d) of the double flow circuit installedwithin the rotary type heat exchange apparatus (1000) are respectivelyinstalled with the unidirectional fluid pumps (120 a)(120 b) beingcapable of producing negative or positive pressure to constitute thedouble flow circuit fluid pumping device (123), thereby by the operativecontrol device (250) to operative control the flow rate of the heatexchange fluid pumped by the double fluid circuit fluid pumping device(123) driven by the power source (300), as well as to operative controlthe rotating speed of the rotary type total heat exchange rotating disk(200) driven by the rotating disk rotationally driving device (110);

The power source (300): It is the device including AC or DC city powersystem or independent power supply device to provide power source forthe operation of the rotary type heat exchange apparatus with automaticexchange flow rate modulation;

The operative control device (250): It is constituted byelectromechanical components, solid state electronic components, ormicroprocessors and related software and operative control interfaces tooperatively control the unidirectional fluid pumps (120 a)(120 b) of thedouble flow circuit fluid pumping device (123) by: 1) operativelycontrolling the switching functional operation; or 2) operativelycontrolling the flow rate of pumping heat exchange fluid; or 3)operatively controlling the temperature distribution status between thefluid and the rotary type total heat exchange rotating disk (200); or 4)operatively controlling the humidity distribution status of the rotarytype total heat exchange rotating disk (200); or 5) operativelycontrolling the rotating speed of the rotary type total heat exchangerotating disk (200) driven by the rotating disk rotationally drivingdevice (110); or 6) integrally operatively controlling at least two ofsaid items 1), 2), 3), 4) & 5) in combination;

The rotating disk rotationally driving device (110): It is constitutedby electric motor or other rotational power source with variable speedtransmission device (111) for driving the rotary type total heatexchange rotating disk (200) to rotate and modulating its rotating speedto change its heat exchange characteristics;

The rotary type total heat exchange rotating disk (200): It isrotationally driven by the rotating disk rotationally driving device(110), wherein its disk is internally provided with two porous fluidcircuit areas for passing through different directional fluid flows andhas the heat absorbing or dissipating as well as humidity absorbing ordissipating function, the two fluid circuits of the rotary type totalheat exchange rotating disk (200) are respectively individually madewith two fluid ports for respectively pumping two fluid streams, whereinthe two fluid flow circuits are mutually isolated, thereby allowing thefluids in different flow directions to pass through the rotary typetotal heat exchange rotating disk (200) driven by the rotating diskrotationally driving device (110) for total heat exchange functionoperations;

The timings to operatively control the flow rate of heat exchange fluidand/or the rotating speed of rotary type total heat exchange rotatingdisk (200) driven by rotating disk rotationally driving device (110) arethat: 1) the fluid flow rate and change timing are preset in the openloop operative control; or 2) it is randomly manually operativelycontrolled; or 3) to install both or at least one of the temperaturedetecting device (11), and humidity detecting device (21) at theposition capable of directly or indirectly detecting the temperaturevariation, or humidity variation of the pumping exchange fluid, whereinthe detected signals are referred to determine the operating timing foroperatively controlling the flow rate of pumping exchange fluid and/orthe rotating speed of the rotary type total heat exchange rotating disk(200) driven by the rotating disk rotationally driving device (110);

The unidirectional fluid pump (120 a) and unidirectional fluid pump (120b) can also be installed to the fluid ports (a)(d) or installed to thefluid ports (b)(c) in said embodiment of FIG. 5, wherein oneunidirectional fluid pump is pumped in positive pressure while the otherunidirectional fluid pump is pumped in negative pressure so as to allowthe two fluid streams to pass through the rotary type total heatexchange rotating disk (200) in different pumping flow directions;

The aforesaid embodiment of FIG. 5 is further installed a heater (130)in the fluid exchange flow circuit of the rotary type total heatexchange rotating disk (200) to enhance the dehumidificationperformance, wherein the heater is actuated by electric energy or othertemperature controllable heat generating sources;

In addition, it is further through the operative control device (250) torefer to detected values of the temperature detecting device (11),humidity detecting device (21) to operatively control the heating timingand heating thermal energy value of the heater (130);

FIG. 6 is a schematic view of the structural principle of the embodimentshowing that the present invention is further installed with thetemperature detecting device and the gaseous or liquid state compositiondetecting device to operatively control the flow rates of the heatexchange fluids;

As shown in FIG. 6, the present invention is mainly constituted by thatthe fluid port (b) and fluid port (d) among the fluid port (a), fluidport (b), fluid port (c), and fluid port (d) of the double flow circuitof the rotary type heat exchange apparatus (1000) are respectivelyinstalled with the unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure to constitute thedouble flow circuit fluid pumping device (123), and it is through thepower of power source (300) and operative control of the operativecontrol device (250) to drive the unidirectional fluid pumps (120 a)(120b) of the double flow circuit fluid pumping device (123) being capableof producing negative pressure or positive pressure for pumping the twofluids to pass through the rotary type heat exchange rotating disk (100)in different flow directions, and the flow circuits of the two fluidstreams in different flow directions are mutually isolated, wherein:

The rotary type heat exchange apparatus (1000) and the unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure can be integrally combined or separately installed toconstitute the double flow circuit fluid pumping device (123) function,and the two unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure are respectivelyinstalled to the fluid port (b) and the fluid port (d) so as to pump thefluid in different pumping flow directions; said two unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure are respectively driven by the electric motorindividually or are commonly driven by the same motor, wherein they areoperatively controlled by the operative control device (250) to operatein one or more than one functional modes of the following, including: 1)the two unidirectional fluid pumps (120 a)(120 b) are pumped in negativepressure for pumping the two fluid streams in different pumping flowdirections; 2) the two unidirectional fluid pumps (120 a)(120 b) arepumped in positive pressure for pumping the two fluid streams indifferent pumping flow directions; in said two functional modeoperations of said 1) & 2), the two fluid streams are pumped to passthrough different areas of the rotary type heat exchange rotating disk(100), the flow circuits of the two fluid streams are mutually isolated,and the flow directions of the two fluid streams are contrary to eachother;

At least one temperature detecting device (11) and at least one gaseousor liquid state fluid composition detecting device (31) are installed atthe positions capable of directly or indirectly detecting thetemperature variation of the pumping exchange fluid and the compositionvariation of the pumping gaseous or liquid state fluid, includinginstalling both or at least one detecting device, wherein the detectedsignals are referred as the operating timing for the operative controldevice (250); including 1) operatively controlling the flow rate of theexchange fluid pumped by the double flow circuit fluid pumping device(123); or 2) operatively controlling the rotating speed of the rotatingspeed of the rotary type heat exchange rotating disk (100) driven by therotating disk rotationally driving device (110); or 3) operativelycontrolling said items 1) & 2) simultaneously;

Said temperature detecting device (11) and gaseous or liquid state fluidcomposition detecting device (31) are integrally combined orindividually separately installed;

The double flow circuit fluid pumping device (123): It is constituted byat least two unidirectional fluid pumps (120 a)(120 b), wherein thefluid port (b) and fluid port (d) among the fluid port (a), fluid port(b), fluid port (c), and fluid port (d) of the double flow circuitinstalled within the rotary type heat exchange apparatus (1000) arerespectively installed with the unidirectional fluid pumps (120 a)(120b) being capable of producing negative or positive pressure toconstitute the double flow circuit fluid pumping device (123), therebyby the operative control device (250) to operative control the flow rateof the heat exchange fluid pumped by the double fluid circuit fluidpumping device (123) driven by the power source (300), as well as tooperative control the rotating speed of the rotary type heat exchangerotating disk (100) driven by the rotating disk rotationally drivingdevice (110);

The power source (300): It is the device including AC or DC city powersystem or independent power supply device to provide power source forthe operation of the rotary type heat exchange apparatus with automaticexchange flow rate modulation;

The operative control device (250): It is constituted byelectromechanical components, solid state electronic components, ormicroprocessors and related software and operative control interfaces tooperatively control the unidirectional fluid pumps (120 a)(120 b) of thedouble flow circuit fluid pumping device (123) by: 1) operativelycontrolling the switching functional operation; or 2) operativelycontrolling the flow rate of pumping heat exchange fluid; or 3)operatively controlling the temperature distribution status between thefluid and the rotary type heat exchange rotating disk (100); or 4)operatively controlling the composition interaction status of betweenthe gaseous or liquid state fluids for heat exchange at the two sides ofthe rotary type heat exchange apparatus (1000);or 5) operativelycontrolling the rotating speed of the rotary type heat exchange rotatingdisk (100) driven by the rotating disk rotationally driving device(110); or 6) integrally operatively controlling at least two of saiditems 1), 2), 3), 4) & 5)in combination;

The rotating disk rotationally driving device (110): It is constitutedby electric motor or other rotational power source with variable speedtransmission device (111) for driving the rotary type heat exchangerotating disk (100) to rotate and modulating its rotating speed tochange its heat exchange characteristics;

The rotary type heat exchange rotating disk (100): It is rotationallydriven by the rotating disk rotationally driving device (110), whereinits disk is internally provided with two porous fluid circuit areas forpassing through different directional fluid flows and has the heatabsorbing or dissipating function, the two fluid circuits of the rotarytype heat exchange rotating disk are respectively individually made withtwo fluid ports for respectively pumping two fluid streams, wherein thetwo fluid flow circuits are mutually isolated, thereby allowing thefluids in different flow directions to pass through the rotary type heatexchange rotating disk (100) driven by the rotating disk rotationallydriving device (110) for heat exchange function operations;

The timings to operatively control the flow rate of heat exchange fluidand/or the rotating speed of rotary type heat exchange rotating disk(100) driven by rotating disk rotationally driving device (110) arethat: 1) the fluid flow rate and change timing are preset in the openloop operative control; or 2) It is randomly manually operativelycontrolled; or 3) to install at least one temperature detecting device(11) or at least one gaseous or liquid state fluid composition detectingdevice (31) at the position capable of directly or indirectly detectingthe temperature or composition of the pumping gaseous or liquid statefluid, including installing both or at least one detecting device,wherein the detected signals are used as the reference to determine theoperating timing for operatively controlling the flow rate of thepumping exchange fluid or the rotating speed of the rotary type heatexchange rotating disk (100) driven by the rotating disk rotationallydriving device (110);

The unidirectional fluid pump (120 a) and unidirectional fluid pump (120b) can also be installed to the fluid ports (a)(d) or installed to thefluid ports (b)(c) in said embodiment of FIG. 6, wherein oneunidirectional fluid pump is pumped in positive pressure while the otherunidirectional fluid pump is pumped in negative pressure so as to allowthe two fluid streams to pass through the rotary type heat exchangerotating disk (100) in different pumping flow directions.

FIG. 7 is a schematic view of the structural principle of the embodimentshowing that the present invention is further installed with thetemperature detecting device, the humidity detecting device and thegaseous or liquid state composition detecting device to operativelycontrol the flow rates of the total heat exchange fluids;

As shown in FIG. 7, the present invention is mainly constituted by thatthe fluid port (b) and fluid port (d) among the fluid port (a), fluidport (b), fluid port (c), and fluid port (d) of the double flow circuitof the rotary type heat exchange apparatus (1000) are respectivelyinstalled with the unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure to constitute thedouble flow circuit fluid pumping device (123), thereby by the operativecontrol device (250) to operative control the unidirectional fluid pumps(120 a)(120 b) capable of producing negative pressure or positivepressure of the double flow circuit fluid pumping device (123) beingdriven by the power source (300), wherein the pumping two fluid streamspass through the rotary type total heat exchange rotating disk (200) indifferent areas, and the flow directions of the two fluid streams aredifferent and mutually isolated, wherein:

The rotary type heat exchange apparatus (1000) and the unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure can be integrally combined or separately installed toconstitute the double flow circuit fluid pumping device (123) function,and the two unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure are respectivelyinstalled to the fluid port (b) and the fluid port (d) so as to pump thefluid in different pumping flow directions; said two unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure are respectively driven by the electric motorindividually or are commonly driven by the same motor, wherein they areoperatively controlled by the operative control device (250) to operatein one or more than one functional modes of the following, including: 1)the two unidirectional fluid pumps (120 a)(120 b) are pumped in negativepressure for pumping the two fluid streams in different pumping flowdirections; 2) the two unidirectional fluid pumps (120 a)(120 b) arepumped in positive pressure for pumping the two fluid streams indifferent pumping flow directions; in said two functional modeoperations of said 1) & 2), the two fluid streams are pumped to passthrough different areas of the rotary type total heat exchange rotatingdisk (200), the flow circuits of the two fluid streams are mutuallyisolated, and the flow directions of the two fluid streams are contraryto each other;

At least one temperature detecting device (11), at least one humiditydetecting device (21), or at least one gaseous or liquid state fluidcomposition detecting device (31) are installed at the positions capableof directly or indirectly detecting the temperature variation, humidityvariation, or gaseous or liquid state fluid composition variation of thepumping exchange fluid, including installing three or at least onedetecting device, wherein the detected signals are used as thereferences to determine the operating timing of the exchange fluid flowrate pumped by the double flow circuit fluid pumping device (123) beingoperatively controlled by the operative control device (250);including 1) operatively controlling the flow rate of the exchange fluidpumped by the double flow circuit fluid pumping device (123); or 2)operatively controlling the rotating speed of the rotary type total heatexchange rotating disk (200) driven by the rotating disk rotationallydriving device (110); or 3) operatively controlling said items 1) & 2)simultaneously;

Said temperature detecting device (11), humidity detecting device (21)and gaseous or liquid state fluid composition detecting device (31) areintegrally combined or individually separately installed;

The double flow circuit fluid pumping device (123): It is constituted byat least two unidirectional fluid pumps (120 a)(120 b), wherein thefluid port (b) and fluid port (d) of the double flow circuit installedwithin the rotary type heat exchange apparatus (1000) are respectivelyinstalled with the unidirectional fluid pumps (120 a)(120 b) beingcapable of producing negative or positive pressure to constitute thedouble flow circuit fluid pumping device (123), thereby by the operativecontrol device (250) to operative control the flow rate of the heatexchange fluid pumped by the double fluid circuit fluid pumping device(123) driven by the power source (300), as well as to operative controlthe rotating speed of the rotary type total heat exchange rotating disk(200) driven by the rotating disk rotationally driving device (110);

The power source (300): It is the device including AC or DC city powersystem or independent power supply device to provide power source forthe operation of the rotary type heat exchange apparatus with automaticexchange flow rate modulation;

The operative control device (250): It is constituted byelectromechanical components, solid state electronic components, ormicroprocessors and related software and operative control interfaces tooperatively control the unidirectional fluid pumps (120 a)(120 b) of thedouble flow circuit fluid pumping device (123) by: 1) operativelycontrolling the switching functional operation; or 2) operativelycontrolling the flow rate of pumping heat exchange fluid; or 3)operatively controlling the temperature distribution status between thefluid and the rotary type total heat exchange rotating disk (200); or 4)operatively controlling the humidity distribution status of the rotarytype total heat exchange rotating disk (200); or 5) operativelycontrolling the composition interaction status between the gaseous orliquid state fluids for heat exchange at the two sides of the rotarytype heat exchange apparatus (1000);or 6) operatively controlling therotating speed of the rotary type total heat exchange rotating disk(200) driven by the rotating disk rotationally driving device (110); or7) integrally operatively controlling at least two of said items 1), 2),3), 4), 5) & 6) in combination;

The rotating disk rotationally driving device (110): It is constitutedby electric motor or other rotational power source with variable speedtransmission device (111) for driving the rotary type total heatexchange rotating disk (200) to rotate and modulating its rotating speedto change its heat exchange characteristics;

The rotary type total heat exchange rotating disk (200): It isrotationally driven by the rotating disk rotationally driving device(110), wherein its disk is internally provided with two porous fluidcircuit areas for passing through different directional fluid flows andhas the heat absorbing or dissipating as well as humidity absorbing ordissipating function, the two fluid circuits of the rotary type totalheat exchange rotating disk (200) are respectively individually madewith two fluid ports for respectively pumping two fluid streams, whereinthe two fluid flow circuits are mutually isolated, thereby allowing thefluids in different flow directions to pass through the rotary typetotal heat exchange rotating disk (200) driven by the rotating diskrotationally driving device (110) for total heat exchange functionoperations;

The timings to operatively control the flow rate of heat exchange fluidand/or the rotating speed of rotary type total heat exchange rotatingdisk (200) driven by rotating disk rotationally driving device (110) arethat: 1) the fluid flow rate and change timing are preset in the openloop operative control; or 2) it is randomly manually operativelycontrolled; or 3) to install three or at least one kind of detectingdevices of at least one temperature detecting device (11), at least onehumidity detecting device (21), or at least one gaseous or liquid statefluid composition detecting device (31) at the position capable ofdirectly or indirectly detecting the temperature variation, humidityvariation, or gaseous or liquid state fluid composition variation of thepumping exchange fluid, wherein the detected signals are used as thereference to determine the operating timing for operatively controllingthe flow rate of the pumping fluid or the rotating speed of the rotarytype total heat exchange rotating disk (200) driven by the rotating diskrotationally driving device (110);

The unidirectional fluid pump (120 a) and unidirectional fluid pump (120b) can also be installed to the fluid ports (a)(d) or installed to thefluid ports (b)(c) in said embodiment of FIG. 7, wherein oneunidirectional fluid pump is pumped in positive pressure while the otherunidirectional fluid pump is pumped in negative pressure so as to allowthe two fluid streams to pass through the rotary type total heatexchange rotating disk (200) in different pumping flow directions;

The aforesaid embodiment of FIG. 7 is further installed a heater (130)in the fluid exchange flow circuit of the rotary type heat exchangerotating disk (200) to enhance the dehumidification performance, whereinthe heater is actuated by electric energy or other temperaturecontrollable heat generating sources;

In addition, it is further through the operative control device (250) torefer to detected values of the temperature detecting device (11),humidity detecting device (21), gaseous or liquid state compositiondetecting device (31) to operatively control the heating timing andheating thermal energy value of the heater (130);

For the rotary type heat exchange apparatus with automatic flow rateexchange modulation of present invention, the structural types of therotary type heat exchange rotating disk or the rotary type total heatexchange rotating disk include one or more than one characteristic ofthe following: 1) the tubular structure in linear or other geometricshape; or 2) the multi-layer structure constituted by the gaseous orliquid state liquid fluid circuits; or 3) one or more than one fluidcircuit in series connection, parallel connection, or series andparallel connection;

The rotary type heat exchange apparatus with automatic flow rateexchange modulation of present invention is further installed with thethree or at least one or more than one detecting devices of thetemperature detecting device (11), humidity detecting device (21), andgaseous or liquid state fluid composition detecting device (31), whereinthe installation positions include both or one of the positions near tofluid port (a) and fluid port (b), or both or one of the positions nearto fluid port (c) and fluid port (d) of the rotary type heat exchangeapparatus (1000), rotary type heat exchange rotating disk (100), orrotary type total heat exchange rotating disk (200), or the otherpositions capable of detecting the temperature, humidity or compositionof the exchange fluid during heat exchange operation, and the number ofthem could be one or more than one to provide detected signals forreference by one or more than functional operations of the following: 1)for reference to operatively control the double flow circuit fluidpumping device (123) for modulating the flow speed or flow rate of thepumping fluid; or 2) for reference to operatively control the openingpercentage of the fluid valve for modulating the flow speed or flow rateof the pumping fluid;

For said temperature detecting device (11), humidity detecting device(21), and gaseous or liquid state fluid composition detecting device(31), all of the detecting devices are integrally combined, or part ofthe detecting devices are integrally combined, or they are individuallyseparately installed;

Said double flow circuit fluid pumping device (123) of the presentinvention constituted by two unidirectional fluid pumps (120 a)(120 b)is configured for pumping gaseous or liquid state fluids, wherein thetwo unidirectional fluid pumps (120 a)(120 b) constituting the doubleflow circuit fluid pumping device (123) except for being driven byindividually installed electric motors or by a common electric motor,they can also be driven by engine power, or the mechanical or electricpower converted from other wind power, thermal energy,temperature-difference energy, or solar energy.

The operative control device (250) of the present invention is equippedwith the electric motor, engine power, or mechanical or electric powergenerated or converted from other wind power, thermal energy,temperature-difference energy, or solar energy for driving variousunidirectional fluid pumps (120 a)(120 b), or the rotating diskrotationally driving device (110), or capable of operatively controllingthe operating timing of the fluid pumps or fluid valves thereby changingthe flow directions of the two fluid streams passing through the rotarytype heat exchange rotating disk (100), or capable of operativelycontrolling the rotating speed of the rotary type heat exchange rotatingdisk (100) or the rotary type total heat exchange rotating disk (200)driven by the rotating disk rotationally driving device (110) to furtheroperatively control partial or all modulating functions of the rotatingspeed, flow rate, fluid pressure of the fluid pumps.

For said rotary type heat exchange apparatus with automatic flow rateexchange modulation of present invention, it is further through theoperative control device (250) to operatively control the flow rate ofthe pumping fluid pumped by the double flow circuit fluid pumping device(123) and/or to operatively control the rotating speed of the rotarytype heat exchange rotating disk (100) or the rotary type total heatexchange rotating disk (200) driven by the rotating disk rotationallydriving device (110), wherein the operating modes include one or morethan one of the following:

-   1) The adjustment or setting is manually operatively controlled;-   2) The operative control is referring to the signal detected by at    least one installed temperature detecting device;-   3) The operative control is referring to the signal detected by at    least one installed humidity detecting device;-   4) The operative control is referring to the signal detected by at    least one installed gaseous or liquid state fluid composition    detecting device;-   5) The operative control is performed by combining the two or more    than two methods of items 1)˜4).

In setting up the flow rate operative control function of the rotarytype heat exchange apparatus with automatic flow rate exchangemodulation of present invention, the fluid flow rate operative controlrange including the stepped or stepless fluid flow rate modulations fromcease of transportation to maximum transportation rate is relied on oneor more than one of the following devices to change the fluid flow rate,wherein it includes:

-   1) It is through operatively controlling the pumping rotating speed    of the double flow circuit fluid pumping device (123) comprising two    unidirectional fluid pumps (120 a)(120 b) within the range from    cease of transportation to maximum transportation rate to further    operatively control the fluid flow rate;-   2) It is through adopting the double flow circuit fluid pumping    device (123) being installed with operatively controllable fluid    inlet/outlet valves to operatively control the opening of the fluid    inlet/outlet valves of the double flow circuit fluid pumping device    (123) to further operatively control the fluid flow rate;-   3) It is through operatively controlling any one device of items    1)˜2) to pump the fluid intermittently so as to modulate the average    flow rate by the time ratio of pumping on/off.

The flow rate ratio between the two fluid streams of the said rotarytype heat exchange apparatus with automatic flow rate exchangemodulation of present invention for passing through the rotary type heatexchange apparatus (1000) during operation include one or more than oneratio mode of the following:

-   1) The flow rate of fluid in one flow circuit is greater than the    one in the other flow circuit;-   2) The flow rates of the fluids in both flow circuits are the same;-   3) Two fluid pumps in different pumping flow directions are    alternatively operated to alternatively pump the two fluid streams    in opposite flow directions;

For said rotary type heat exchange apparatus with automatic flow rateexchange modulation of present invention, beside of the operatingfunction of pumping fluids of the double flow circuit in different flowdirections, the double flow circuit fluid pumping device (123) beingconstituted by two fluid pumps capable of bidirectional pumping isthrough operatively controlling the pumping flow directions of the twofluid streams to further have one or more than one special operatingmodes of the following:

-   1) Operatively controlling the fluids in two flow circuits to be    pumped in the same flow directions for pumping in fluids;-   2) Operatively controlling the fluids in two flow circuits to be    reversely pumped in the same flow directions for discharging fluids;-   3) Operatively controlling the fluids in two flow circuits to be    periodically pumped in positive and reverse flow directions for    pumping in fluids in the same flow directions and discharging fluids    in reverse flow directions.

The same directional pumping function of said two fluid streams can beapplied to meet the needs for emergency additional fluid flow ratepumping in or out.

1. A rotary type heat exchange apparatus with automatic flow rateexchange modulation the operating function of automatic exchange fluidflow rate modulation so as to timely change the temperature distributionstatus between the fluid and the heat exchange rotating disk, or tomodulate the composition ratio of the gaseous or liquid state pumpingfluid, wherein the heat exchange rotating disk inside the rotary typeheat exchange apparatus being insertingly installed or coated withpenetrating type or absorbing type moisture absorbing material, or theheat exchange rotating disk itself having the concurrentdehumidification function constitute the dehumidification effect of thetotal heat exchange function, wherein it is mainly constituted by thatthe fluid port (b) and the fluid port (d) among the fluid port (a),fluid port (b), fluid port (c), and fluid port (d) of the double flowcircuit of the rotary type heat exchange apparatus (1000) arerespectively installed with the unidirectional fluid pumps (120 a)(120b) capable of producing negative pressure or positive pressure toconstitute the double flow circuit fluid pumping device (123), and it isthrough the power of power source (300) and operative control of theoperative control device (250) to drive the unidirectional fluid pumps(120 a)(120 b) of the double flow circuit fluid pumping device (123)being capable of producing negative pressure or positive pressure forpumping the two fluids to pass through the rotary type heat exchangerotating disk (100) in different areas and different flow directions,and the flow circuits of the two fluid streams are mutually isolated,wherein: The rotary type heat exchange apparatus (1000) and theunidirectional fluid pumps (120 a)(120 b) capable of producing negativepressure or positive pressure can be integrally combined or separatelyinstalled to constitute the double flow circuit fluid pumping device(123) function, and the two unidirectional fluid pumps (120 a)(120 b)capable of producing negative pressure or positive pressure arerespectively installed to the fluid port (b) and the fluid port (d) soas to pump the fluid in different pumping flow directions; said twounidirectional fluid pumps (120 a)(120 b) capable of producing negativepressure or positive pressure are respectively driven by the electricmotor individually or are commonly driven by the same motor, whereinthey are operatively controlled by the operative control device (250) tooperate in one or more than one functional modes of the following,including: 1) the two unidirectional fluid pumps (120 a)(120 b) arepumped in negative pressure for pumping the two fluid streams indifferent pumping flow directions; 2) the two unidirectional fluid pumps(120 a)(120 b) are pumped in positive pressure for pumping the two fluidstreams in different pumping flow directions; in said two functionalmode operations of said 1) & 2), the two fluid streams are pumped topass through different areas of the rotary type heat exchange rotatingdisk (100), the flow circuits of the two fluid streams are mutuallyisolated, and the flow directions of the two fluid streams are contraryto each other; The double flow circuit fluid pumping device (123): It isconstituted by at least two unidirectional fluid pumps (120 a)(120 b),wherein the fluid port (b) and the fluid port (d) among the fluid port(a), fluid port (b), fluid port (c), and fluid port (d) of the doubleflow circuit installed within the rotary type heat exchange apparatus(1000) are respectively installed with the unidirectional fluid pumps(120 a)(120 b) being capable of producing negative or positive pressureto constitute the double flow circuit fluid pumping device (123),thereby by the operative control device (250) to operative control theflow rate of the heat exchange fluid pumped by the double fluid circuitfluid pumping device (123) driven by the power source (300), as well asto operative control the rotating speed of the rotary type heat exchangerotating disk (100) driven by the rotating disk rotationally drivingdevice (110); The power source (300): It is the device including AC orDC city power system or independent power supply device to provide powersource for the operation of the rotary type heat exchange apparatus withautomatic exchange flow rate modulation; The operative control device(250): It is constituted by electromechanical components, solid stateelectronic components, or microprocessors and related software andoperative control interfaces to operatively control the unidirectionalfluid pumps (120 a)(120 b) of the double flow circuit fluid pumpingdevice (123) by: 1) operatively controlling the switching functionaloperation; or 2) operatively controlling the flow rate of pumping heatexchange fluid; or 3) operatively controlling the temperaturedistribution status between the fluid and rotary type heat exchangerotating disk (100); or 4) operatively controlling the rotating speed ofthe rotary type heat exchange rotating disk (100) driven by the rotatingdisk rotationally driving device (110); or 5) integrally operativelycontrolling at least two of said items 1), 2), 3) & 4) in combination;The rotating disk rotationally driving device (110): It is constitutedby electric motor or other rotational power source with variable speedtransmission device (111) for driving the rotary type heat exchangerotating disk (100) to rotate and modulating its rotating speed tochange its heat exchange characteristics; The rotary type heat exchangerotating disk (100): It is rotationally driven by the rotating diskrotationally driving device (110), wherein its disk is internallyprovided with two porous fluid circuit areas for passing throughdifferent directional fluid flows and has the heat absorbing ordissipating function, the two fluid circuits of the rotary type heatexchange rotating disk are respectively provided with two fluid portsfor respectively pumping two fluid streams, wherein the passage of thetwo fluid streams are mutually isolated, thereby allowing the fluids indifferent flowing directions to pass through the rotary type heatexchange rotating disk (100) rotationally driven by the rotating diskrotationally driving device (110) for heat exchange function operations;The timings to operatively control the flow rate of heat exchange fluidand/or the rotating speed of rotary type heat exchange rotating disk(100) driven by rotating disk rotationally driving device (110) arethat: 1) the fluid flow rate and change timing are preset in the openloop operative control; or 2) it is randomly manually operativelycontrolled.
 2. A rotary type heat exchange apparatus with automatic flowrate exchange modulation as claimed in claim 1, wherein theunidirectional fluid pump (120 a) and unidirectional fluid pump (120 b)can also be installed to the fluid ports (a)(d) or installed to thefluid ports (b)(c), wherein one unidirectional fluid pump is pumped inpositive pressure while the other unidirectional fluid pump is pumped innegative pressure so as to allow the two fluid streams to pass throughthe rotary type heat exchange rotating disk (100) in different pumpingflow directions.
 3. A rotary type heat exchange apparatus with automaticflow rate exchange modulation as claimed in claim 1, wherein it isfurther installed with the temperature detecting device to operativelycontrol the flow rates of the heat exchange fluids, whereof it is mainlyconstituted by that the fluid port (b) and fluid port (d) among thefluid port (a), fluid port (b), fluid port (c), and fluid port (d) ofthe double flow circuit of the rotary type heat exchange apparatus(1000) are respectively installed with the unidirectional fluid pumps(120 a)(120 b) capable of producing negative pressure or positivepressure to constitute the double flow circuit fluid pumping device(123), and it is through the power of power source (300) and operativecontrol of the operative control device (250) to drive theunidirectional fluid pumps (120 a)(120 b) of the double flow circuitfluid pumping device (123) being capable of producing negative pressureor positive pressure for pumping the two fluids to pass through therotary type heat exchange rotating disk (100) in different areas anddifferent flow directions, and the flow circuits of the two fluidstreams are mutually isolated, wherein: The rotary type heat exchangeapparatus (1000) and the unidirectional fluid pumps (120 a)(120 b)capable of producing negative pressure or positive pressure can beintegrally combined or separately installed to constitute the doubleflow circuit fluid pumping device (123) function, and the twounidirectional fluid pumps (120 a)(120 b) capable of producing negativepressure or positive pressure are respectively installed to the fluidport (b) and the fluid port (d) so as to pump the fluid in differentpumping flow directions; said two unidirectional fluid pumps (120 a)(120b) capable of producing negative pressure or positive pressure arerespectively driven by the electric motor individually or are commonlydriven by the same motor, wherein they are operatively controlled by theoperative control device (250) to operate in one or more than onefunctional modes of the following, including: 1) the two unidirectionalfluid pumps (120 a)(120 b) are pumped in negative pressure for pumpingthe two fluid streams in different pumping flow directions; 2) the twounidirectional fluid pumps (120 a)(120 b) are pumped in positivepressure for pumping the two fluid streams in different pumping flowdirections; in said two functional mode operations of said 1) & 2), thetwo fluid streams are pumped to pass through different areas of therotary type heat exchange rotating disk (100), the flow circuits of thetwo fluid streams are mutually isolated, and the flow directions of thetwo fluid streams are contrary to each other; At least one temperaturedetecting device (11) is installed at the position capable of directlyor indirectly detecting the temperature variation of the pumpingexchange fluid, wherein the detected signal is referred as the operativecontrol timing for the operative control device (250); including: 1)operatively controlling the flow rate of the exchange fluid pumped bythe double flow circuit fluid pumping device (123); or 2) operativelycontrolling the rotating speed of the rotary type heat exchange rotatingdisk (100) driven by the rotating disk rotationally driving device(110); or 3) operatively controlling said items 1) & 2) simultaneously;The double flow circuit fluid pumping device (123) : It is constitutedby at least two unidirectional fluid pumps (120 a)(120 b), wherein thefluid port (b) and fluid port (d) among the fluid port (a), fluid port(b), fluid port (c), and fluid port (d) of the double flow circuitinstalled within the rotary type heat exchange apparatus (1000) arerespectively installed with the unidirectional fluid pumps (120 a)(120b) being capable of producing negative or positive pressure toconstitute the double flow circuit fluid pumping device (123), therebyby the operative control device (250) to operative control the flow rateof the heat exchange fluid pumped by the double fluid circuit fluidpumping device (123) driven by the power source (300), as well as tooperative control the rotating speed of the rotary type heat exchangerotating disk (100) driven by the rotating disk rotationally drivingdevice (110); The power source (300): It is the device including AC orDC city power system or independent power supply device to provide powersource for the operation of the rotary type heat exchange apparatus withautomatic exchange flow rate modulation; The operative control device(250): It is constituted by electromechanical components, solid stateelectronic components, or microprocessors and related software andoperative control interfaces to operatively control the unidirectionalfluid pumps (120 a)(120 b) of the double flow circuit fluid pumpingdevice (123) by: 1) operatively controlling the switching functionaloperation; or 2) operatively controlling the flow rate of pumping heatexchange fluid; or 3) operatively controlling the temperaturedistribution status between the fluid and the rotary type heat exchangerotating disk (100); or 4) operatively controlling the rotating speed ofthe rotary type heat exchange rotating disk (100) driven by the rotatingdisk rotationally driving device (110); or 5) integrally operativelycontrolling at least two of said items 1), 2), 3) & 4) in combination;The rotating disk rotationally driving device (110): It is constitutedby electric motor or other rotational power source with variable speedtransmission device (111) for driving the rotary type heat exchangerotating disk (100) to rotate and modulating its rotating speed tochange its heat exchange characteristics; The rotary type heat exchangerotating disk (100): It is rotationally driven by the rotating diskrotationally driving device (1 O), wherein its disk is internallyprovided with two porous fluid circuit areas for passing throughdifferent directional fluid flows and has the heat absorbing ordissipating function, the two fluid circuits of the rotary type heatexchange rotating disk are respectively provided with two fluid portsfor respectively pumping two fluid streams, wherein the two fluid flowcircuits are mutually isolated, thereby allowing the fluids in differentflowing directions to pass through the rotary type heat exchangerotating disk (100) rotationally driven by the rotating diskrotationally driving device (110) for heat exchange function operations;The timings to operatively control the flow rate of heat exchange fluidand/or the rotating speed of rotary type heat exchange rotating disk(100) driven by rotating disk rotationally driving device (110) arethat: 1) the fluid flow rate and change timing are preset in the openloop operative control; or 2) it is randomly manually operativelycontrolled; or 3) to install at least one temperature detecting device(11) at the position capable of directly or indirectly detecting thetemperature variation, wherein the signals detected by the temperaturedetecting device (11) is referred to determine the operating timing foroperatively controlling the flow rate of pumping exchange fluid and/orthe rotating speed of the rotary type heat exchange rotating disk (100)driven by the rotating disk rotationally driving device (110).
 4. Arotary type heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 3, wherein the unidirectional fluid pump(120 a) and unidirectional fluid pump (120 b) can also be installed tothe fluid ports (a)(d) or installed to the fluid ports (b)(c), whereinone unidirectional fluid pump is pumped in positive pressure while theother unidirectional fluid pump is pumped in negative pressure so as toallow the two fluid streams to pass through the rotary type heatexchange rotating disk (100) in different pumping flow directions.
 5. Arotary type heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 1, wherein it is further installed withthe temperature detecting device and humidity detecting device tooperatively control the flow rates of the total heat exchange fluid,whereof it is mainly constituted by that the fluid port (b) and fluidport (d) among the fluid port (a), fluid port (b), fluid port (c), andfluid port (d) of the double flow circuit of the rotary type heatexchange apparatus (1000) are respectively installed with theunidirectional fluid pumps (120 a)(120 b) capable of producing negativepressure or positive pressure to constitute the double flow circuitfluid pumping device (123), thereby by the operative control device(250) to operative control the unidirectional fluid pumps (120 a)(120 b)capable of producing negative pressure or positive pressure of thedouble flow circuit fluid pumping device (123) being driven by the powersource (300), wherein the pumping two fluid streams pass through therotary type total heat exchange rotating disk (200) in different areas,and the flow directions of the two fluid streams are different andmutually isolated, wherein: The rotary type heat exchange apparatus(1000) and the unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure can be integrallycombined or separately installed to constitute the double flow circuitfluid pumping device (123) function, and the two unidirectional fluidpumps (120 a)(120 b) capable of producing negative pressure or positivepressure are respectively installed to the fluid port (b) and the fluidport (d) so as to pump the fluid in different pumping flow directions;said two unidirectional fluid pumps (120 a)(120 b) capable of producingnegative pressure or positive pressure are respectively driven by theelectric motor individually or are commonly driven by the same motor,wherein they are operatively controlled by the operative control device(250) to operate in one or more than one functional modes of thefollowing, including: 1) the two unidirectional fluid pumps (120 a)(120b) are pumped in negative pressure for pumping the two fluid streams indifferent pumping flow directions; 2) the two unidirectional fluid pumps(120 a)(120 b) are pumped in positive pressure for pumping the two fluidstreams in different pumping flow directions; in said two functionalmode operations of said 1) & 2), the two fluid streams are pumped topass through different areas of the rotary type total heat exchangerotating disk (200), the flow circuits of the two fluid streams aremutually isolated, and the flow directions of the two fluid streams arecontrary to each other; At least one temperature detecting device (11)and at least one humidity detecting device (21) are installed at thepositions capable of directly or indirectly detecting the temperatureand humidity variations of the pumping exchange fluid, includinginstalling both or at least one detecting device, wherein the detectedsignals are referred as the operating timing for the operative controldevice (250); including: 1) operatively controlling the flow rate of theexchange fluid pumped by the double flow circuit fluid pumping device(123); or 2) operatively controlling the rotating speed of the rotarytype total heat exchange rotating disk (200) driven by rotating diskrotationally driving device (110); or 3) operatively controlling saiditems 1) & 2) simultaneously; Said temperature detecting device (11) andhumidity detecting device (21) are integrally combined or individuallyseparately installed; The double flow circuit fluid pumping device(123): It is constituted by at least two unidirectional fluid pumps (120a)(120 b), wherein the fluid port (b) and fluid port (d) of the doubleflow circuit installed within the rotary type heat exchange apparatus(1000) are respectively installed with the unidirectional fluid pumps(120 a)(120 b) being capable of producing negative or positive pressureto constitute the double flow circuit fluid pumping device (123),thereby by the operative control device (250) to operative control theflow rate of the heat exchange fluid pumped by the double fluid circuitfluid pumping device (123) driven by the power source (300), as well asto operative control the rotating speed of the rotary type total heatexchange rotating disk (200) driven by the rotating disk rotationallydriving device (110); The power source (300): It is the device includingAC or DC city power system or independent power supply device to providepower source for the operation of the rotary type heat exchangeapparatus with automatic exchange flow rate modulation; The operativecontrol device (250): It is constituted by electromechanical components,solid state electronic components, or microprocessors and relatedsoftware and operative control interfaces to operatively control theunidirectional fluid pumps (120 a)(120 b) of the double flow circuitfluid pumping device (123) by: 1) operatively controlling the switchingfunctional operation; or 2) operatively controlling the flow rate ofpumping heat exchange fluid; or 3) operatively controlling thetemperature distribution status between the fluid and the rotary typetotal heat exchange rotating disk (200); or 4) operatively controllingthe humidity distribution status of the rotary type total heat exchangerotating disk (200); or 5) operatively controlling the rotating speed ofthe rotary type total heat exchange rotating disk (200) driven by therotating disk rotationally driving device (110); or 6) integrallyoperatively controlling at least two of said items 1), 2), 3), 4) & 5)in combination; The rotating disk rotationally driving device (110): Itis constituted by electric motor or other rotational power source withvariable speed transmission device (111) for driving the rotary typetotal heat exchange rotating disk (200) to rotate and modulating itsrotating speed to change its heat exchange characteristics; The rotarytype total heat exchange rotating disk (200): It is rotationally drivenby the rotating disk rotationally driving device (110), wherein its diskis internally provided with two porous fluid circuit areas for passingthrough different directional fluid flows and has the heat absorbing ordissipating as well as humidity absorbing or dissipating function, thetwo fluid circuits of the rotary type total heat exchange rotating disk(200) are respectively individually made with two fluid ports forrespectively pumping two fluid streams, wherein the two fluid flowcircuits are mutually isolated, thereby allowing the fluids in differentflow directions to pass through the rotary type total heat exchangerotating disk (200) driven by the rotating disk rotationally drivingdevice (110) for total heat exchange function operations; The timings tooperatively control the flow rate of heat exchange fluid and/or therotating speed of rotary type total heat exchange rotating disk (200)driven by rotating disk rotationally driving device (110) are that: 1)the fluid flow rate and change timing are preset in the open loopoperative control; or 2) it is randomly manually operatively controlled;or 3) to install both or at least one of the temperature detectingdevice (11), and humidity detecting device (21) at the position capableof directly or indirectly detecting the temperature variation, orhumidity variation of the pumping exchange fluid, wherein the detectedsignals are referred to determine the operating timing for operativelycontrolling the flow rate of pumping exchange fluid and/or the rotatingspeed of the rotary type total heat exchange rotating disk (200) drivenby the rotating disk rotationally driving device (110).
 6. A rotary typeheat exchange apparatus with automatic flow rate exchange modulation asclaimed in claim 5, the unidirectional fluid pump (120 a) andunidirectional fluid pump (120 b) can also be installed to the fluidports (a)(d) or installed to the fluid ports (b)(c), wherein oneunidirectional fluid pump is pumped in positive pressure while the otherunidirectional fluid pump is pumped in negative pressure so as to allowthe two fluid streams to pass through the rotary type total heatexchange rotating disk (200) in different pumping flow directions.
 7. Arotary type heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 5, wherein it is further installed aheater (130) in the fluid exchange flow circuit of the rotary type totalheat exchange rotating disk (200) to enhance the dehumidificationperformance, wherein the heater is actuated by electric energy or othertemperature controllable heat generating sources.
 8. A rotary type heatexchange apparatus with automatic flow rate exchange modulation asclaimed in claim 7, wherein it is further through the operative controldevice (250) to refer to detected values of the temperature detectingdevice (11), humidity detecting device (21) to operatively control theheating timing and heating thermal energy value of the heater (130). 9.A rotary type heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 1, wherein it is further installed withthe temperature detecting device and the gaseous or liquid statecomposition detecting device to operatively control the flow rates ofthe heat exchange fluids, whereof it is mainly constituted by that thefluid port (b) and fluid port (d) among the fluid port (a), fluid port(b), fluid port (c), and fluid port (d) of the double flow circuit ofthe rotary type heat exchange apparatus (1000) are respectivelyinstalled with the unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure to constitute thedouble flow circuit fluid pumping device (123), and it is through thepower of power source (300) and operative control of the operativecontrol device (250) to drive the unidirectional fluid pumps (120 a)(120b) of the double flow circuit fluid pumping device (123) being capableof producing negative pressure or positive pressure for pumping the twofluids to pass through the rotary type heat exchange rotating disk (100)in different flow directions, and the flow circuits of the two fluidstreams in different flow directions are mutually isolated, wherein: Therotary type heat exchange apparatus (1000) and the unidirectional fluidpumps (120 a)(120 b) capable of producing negative pressure or positivepressure can be integrally combined or separately installed toconstitute the double flow circuit fluid pumping device (123) function,and the two unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure are respectivelyinstalled to the fluid port (b) and the fluid port (d) so as to pump thefluid in different pumping flow directions; said two unidirectionalfluid pumps (120 a)(120 b) capable of producing negative pressure orpositive pressure are respectively driven by the electric motorindividually or are commonly driven by the same motor, wherein they areoperatively controlled by the operative control device (250) to operatein one or more than one functional modes of the following, including: 1)the two unidirectional fluid pumps (120 a)(120 b) are pumped in negativepressure for pumping the two fluid streams in different pumping flowdirections; 2) the two unidirectional fluid pumps (120 a)(120 b) arepumped in positive pressure for pumping the two fluid streams indifferent pumping flow directions; in said two functional modeoperations of said 1) & 2), the two fluid streams are pumped to passthrough different areas of the rotary type heat exchange rotating disk(100), the flow circuits of the two fluid streams are mutually isolated,and the flow directions of the two fluid streams are contrary to eachother; At least one temperature detecting device (11) and at least onegaseous or liquid state fluid composition detecting device (31) areinstalled at the positions capable of directly or indirectly detectingthe temperature variation of the pumping exchange fluid and thecomposition variation of the pumping gaseous or liquid state fluid,including installing both or at least one detecting device, wherein thedetected signals are referred as the operating timing for the operativecontrol device (250); including 1) operatively controlling the flow rateof the exchange fluid pumped by the double flow circuit fluid pumpingdevice (123); or 2) operatively controlling the rotating speed of therotating speed of the rotary type heat exchange rotating disk (100)driven by the rotating disk rotationally driving device (110); or 3)operatively controlling said items 1) & 2) simultaneously; Saidtemperature detecting device (11) and gaseous or liquid state fluidcomposition detecting device (31) are integrally combined orindividually separately installed; The double flow circuit fluid pumpingdevice (123): It is constituted by at least two unidirectional fluidpumps (120 a)(120 b), wherein the fluid port (b) and fluid port (d)among the fluid port (a), fluid port (b), fluid port (c), and fluid port(d) of the double flow circuit installed within the rotary type heatexchange apparatus (1000) are respectively installed with theunidirectional fluid pumps (120 a)(120 b) being capable of producingnegative or positive pressure to constitute the double flow circuitfluid pumping device (123), thereby by the operative control device(250) to operative control the flow rate of the heat exchange fluidpumped by the double fluid circuit fluid pumping device (123) driven bythe power source (300), as well as to operative control the rotatingspeed of the rotary type heat exchange rotating disk (100) driven by therotating disk rotationally driving device (110); The power source (300):It is the device including AC or DC city power system or independentpower supply device to provide power source for the operation of therotary type heat exchange apparatus with automatic exchange flow ratemodulation; The operative control device (250): It is constituted byelectromechanical components, solid state electronic components, ormicroprocessors and related software and operative control interfaces tooperatively control the unidirectional fluid pumps (120 a)(120 b) of thedouble flow circuit fluid pumping device (123) by: 1) operativelycontrolling the switching functional operation; or 2) operativelycontrolling the flow rate of pumping heat exchange fluid; or 3)operatively controlling the temperature distribution status between thefluid and the rotary type heat exchange rotating disk (100); or 4)operatively controlling the composition interaction status of betweenthe gaseous or liquid state fluids for heat exchange at the two sides ofthe rotary type heat exchange apparatus (1000);or 5) operativelycontrolling the rotating speed of the rotary type heat exchange rotatingdisk (100) driven by the rotating disk rotationally driving device(110); or 6) integrally operatively controlling at least two of saiditems 1), 2), 3), 4) & 5)in combination; The rotating disk rotationallydriving device (110): It is constituted by electric motor or otherrotational power source with variable speed transmission device (111)for driving the rotary type heat exchange rotating disk (100) to rotateand modulating its rotating speed to change its heat exchangecharacteristics; The rotary type heat exchange rotating disk (100): Itis rotationally driven by the rotating disk rotationally driving device(110), wherein its disk is internally provided with two porous fluidcircuit areas for passing through different directional fluid flows andhas the heat absorbing or dissipating function, the two fluid circuitsof the rotary type heat exchange rotating disk are respectivelyindividually made with two fluid ports for respectively pumping twofluid streams, wherein the two fluid flow circuits are mutuallyisolated, thereby allowing the fluids in different flow directions topass through the rotary type heat exchange rotating disk (100) driven bythe rotating disk rotationally driving device (110) for heat exchangefunction operations; The timings to operatively control the flow rate ofheat exchange fluid and/or the rotating speed of rotary type heatexchange rotating disk (100) driven by rotating disk rotationallydriving device (110) are that: 1) the fluid flow rate and change timingare preset in the open loop operative control; or 2) It is randomlymanually operatively controlled; or 3) to install at least onetemperature detecting device (11) or at least one gaseous or liquidstate fluid composition detecting device (31) at the position capable ofdirectly or indirectly detecting the temperature or composition of thepumping gaseous or liquid state fluid, including installing both or atleast one detecting device, wherein the detected signals are used as thereference to determine the operating timing for operatively controllingthe flow rate of the pumping exchange fluid or the rotating speed of therotary type heat exchange rotating disk (100) driven by the rotatingdisk rotationally driving device (110).
 10. A rotary type heat exchangeapparatus with automatic flow rate exchange modulation as claimed inclaim 9, wherein the unidirectional fluid pump (120 a) andunidirectional fluid pump (120 b) can also be installed to the fluidports (a)(d) or installed to the fluid ports (b)(c), wherein oneunidirectional fluid pump is pumped in positive pressure while the otherunidirectional fluid pump is pumped in negative pressure so as to allowthe two fluid streams to pass through the rotary type heat exchangerotating disk (100) in different pumping flow directions.
 11. A rotarytype heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 1, wherein it is further installed withthe temperature detecting device, the humidity detecting device and thegaseous or liquid state composition detecting device to operativelycontrol the flow rates of the total heat exchange fluids, whereof it ismainly constituted by that the fluid port (b) and fluid port (d) amongthe fluid port (a), fluid port (b), fluid port (c), and fluid port (d)of the double flow circuit of the rotary type heat exchange apparatus(1000) are respectively installed with the unidirectional fluid pumps(120 a)(120 b) capable of producing negative pressure or positivepressure to constitute the double flow circuit fluid pumping device(123), thereby by the operative control device (250) to operativecontrol the unidirectional fluid pumps (120 a)(120 b) capable ofproducing negative pressure or positive pressure of the double flowcircuit fluid pumping device (123) being driven by the power source(300), wherein the pumping two fluid streams pass through the rotarytype total heat exchange rotating disk (200) in different areas, and theflow directions of the two fluid streams are different and mutuallyisolated, wherein: The rotary type heat exchange apparatus (1000) andthe unidirectional fluid pumps (120 a)(120 b) capable of producingnegative pressure or positive pressure can be integrally combined orseparately installed to constitute the double flow circuit fluid pumpingdevice (123) function, and the two unidirectional fluid pumps (120a)(120 b) capable of producing negative pressure or positive pressureare respectively installed to the fluid port (b) and the fluid port (d)so as to pump the fluid in different pumping flow directions; said twounidirectional fluid pumps (120 a)(120 b) capable of producing negativepressure or positive pressure are respectively driven by the electricmotor individually or are commonly driven by the same motor, whereinthey are operatively controlled by the operative control device (250) tooperate in one or more than one functional modes of the following,including: 1) the two unidirectional fluid pumps (120 a)(120 b) arepumped in negative pressure for pumping the two fluid streams indifferent pumping flow directions; 2) the two unidirectional fluid pumps(120 a)(120 b) are pumped in positive pressure for pumping the two fluidstreams in different pumping flow directions; in said two functionalmode operations of said 1) & 2), the two fluid streams are pumped topass through different areas of the rotary type total heat exchangerotating disk (200), the flow circuits of the two fluid streams aremutually isolated, and the flow directions of the two fluid streams arecontrary to each other; At least one temperature detecting device (11),at least one humidity detecting device (21), or at least one gaseous orliquid state fluid composition detecting device (31) are installed atthe positions capable of directly or indirectly detecting thetemperature variation, humidity variation, or gaseous or liquid statefluid composition variation of the pumping exchange fluid, includinginstalling three or at least one detecting device, wherein the detectedsignals are used as the references to determine the operating timing ofthe exchange fluid flow rate pumped by the double flow circuit fluidpumping device (123) being operatively controlled by the operativecontrol device (250); including 1) operatively controlling the flow rateof the exchange fluid pumped by the double flow circuit fluid pumpingdevice (123); or 2) operatively controlling the rotating speed of therotary type total heat exchange rotating disk (200) driven by therotating disk rotationally driving device (110); or 3) operativelycontrolling said items 1) & 2) simultaneously; Said temperaturedetecting device (11), humidity detecting device (21) and gaseous orliquid state fluid composition detecting device (31) are integrallycombined or individually separately installed; The double flow circuitfluid pumping device (123): It is constituted by at least twounidirectional fluid pumps (120 a)(120 b), wherein the fluid port (b)and fluid port (d) of the double flow circuit installed within therotary type heat exchange apparatus (1000) are respectively installedwith the unidirectional fluid pumps (120 a)(120 b) being capable ofproducing negative or positive pressure to constitute the double flowcircuit fluid pumping device (123), thereby by the operative controldevice (250) to operative control the flow rate of the heat exchangefluid pumped by the double fluid circuit fluid pumping device (123)driven by the power source (300), as well as to operative control therotating speed of the rotary type total heat exchange rotating disk(200) driven by the rotating disk rotationally driving device (110); Thepower source (300): It is the device including AC or DC city powersystem or independent power supply device to provide power source forthe operation of the rotary type heat exchange apparatus with automaticexchange flow rate modulation; The operative control device (250): It isconstituted by electromechanical components, solid state electroniccomponents, or microprocessors and related software and operativecontrol interfaces to operatively control the unidirectional fluid pumps(120 a)(120 b) of the double flow circuit fluid pumping device (123)by: 1) operatively controlling the switching functional operation; or 2)operatively controlling the flow rate of pumping heat exchange fluid; or3) operatively controlling the temperature distribution status betweenthe fluid and the rotary type total heat exchange rotating disk (200);or 4) operatively controlling the humidity distribution status of therotary type total heat exchange rotating disk (200); or 5) operativelycontrolling the composition interaction status between the gaseous orliquid state fluids for heat exchange at the two sides of the rotarytype heat exchange apparatus (100O);or 6) operatively controlling therotating speed of the rotary type total heat exchange rotating disk(200) driven by the rotating disk rotationally driving device (110); or7) integrally operatively controlling at least two of said items 1), 2),3), 4), 5) & 6) in combination; The rotating disk rotationally drivingdevice (110): It is constituted by electric motor or other rotationalpower source with variable speed transmission device (111) for drivingthe rotary type total heat exchange rotating disk (200) to rotate andmodulating its rotating speed to change its heat exchangecharacteristics; The rotary type total heat exchange rotating disk(200): It is rotationally driven by the rotating disk rotationallydriving device (110), wherein its disk is internally provided with twoporous fluid circuit areas for passing through different directionalfluid flows and has the heat absorbing or dissipating as well ashumidity absorbing or dissipating function, the two fluid circuits ofthe rotary type total heat exchange rotating disk (200) are respectivelyindividually made with two fluid ports for respectively pumping twofluid streams, wherein the two fluid flow circuits are mutuallyisolated, thereby allowing the fluids in different flow directions topass through the rotary type total heat exchange rotating disk (200)driven by the rotating disk rotationally driving device (110) for totalheat exchange function operations; The timings to operatively controlthe flow rate of heat exchange fluid and/or the rotating speed of rotarytype total heat exchange rotating disk (200) driven by rotating diskrotationally driving device (110) are that: 1) the fluid flow rate andchange timing are preset in the open loop operative control; or 2) it israndomly manually operatively controlled; or 3) to install three or atleast one kind of detecting devices of at least one temperaturedetecting device (11), at least one humidity detecting device (21), orat least one gaseous or liquid state fluid composition detecting device(31) at the position capable of directly or indirectly detecting thetemperature variation, humidity variation, or gaseous or liquid statefluid composition variation of the pumping exchange fluid, wherein thedetected signals are used as the reference to determine the operatingtiming for operatively controlling the flow rate of the pumping fluid orthe rotating speed of the rotary type total heat exchange rotating disk(200) driven by the rotating disk rotationally driving device (110). 12.A rotary type heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 1, wherein the unidirectional fluid pump(120 a) and unidirectional fluid pump (120 b) can also be installed tothe fluid ports (a)(d) or installed to the fluid ports (b)(c), whereinone unidirectional fluid pump is pumped in positive pressure while theother unidirectional fluid pump is pumped in negative pressure so as toallow the two fluid streams to pass through the rotary type total heatexchange rotating disk (200) in different pumping flow directions.
 13. Arotary type heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 11, wherein it is further installed aheater (130) in the fluid exchange flow circuit of the rotary type heatexchange rotating disk (200) to enhance the dehumidificationperformance, wherein the heater is actuated by electric energy or othertemperature controllable heat generating sources.
 14. A rotary type heatexchange apparatus with automatic flow rate exchange modulation asclaimed in claim 13, wherein it is further through the operative controldevice (250) to refer to detected values of the temperature detectingdevice (11), humidity detecting device (21), gaseous or liquid statecomposition detecting device (31) to operatively control the heatingtiming and heating thermal energy value of the heater (130).
 15. Arotary type heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 1, wherein the structural types of therotary type heat exchange rotating disk or the rotary type total heatexchange rotating disk include one or more than one characteristic ofthe following: 1) the tubular structure in linear or other geometricshape; or 2) the multi-layer structure constituted by the gaseous orliquid state liquid fluid circuits; or 3) one or more than one fluidcircuit in series connection, parallel connection, or series andparallel connection.
 16. A rotary type heat exchange apparatus withautomatic flow rate exchange modulation as claimed in claim 1, whereinit is further installed with the three or at least one or more than onedetecting devices of the temperature detecting device (11), humiditydetecting device (21), and gaseous or liquid state fluid compositiondetecting device (31), wherein the installation positions include bothor one of the positions near to fluid port (a) and fluid port (b), orboth or one of the positions near to fluid port (c) and fluid port (d)of the rotary type heat exchange apparatus (1000), rotary type heatexchange rotating disk (100), or rotary type total heat exchangerotating disk (200), or the other positions capable of detecting thetemperature, humidity or composition of the exchange fluid during heatexchange operation, and the number of them could be one or more than oneto provide detected signals for reference by one or more than functionaloperations of the following: 1) for reference to operatively control thedouble flow circuit fluid pumping device (123) for modulating the flowspeed or flow rate of the pumping fluid; or 2) for reference tooperatively control the opening percentage of the fluid valve formodulating the flow speed or flow rate of the pumping fluid; Saidtemperature detecting device (11), humidity detecting device (21), andgaseous or liquid state fluid composition detecting device (31), all ofthe detecting devices are integrally combined, or part of the detectingdevices are integrally combined, or they are individually separatelyinstalled.
 17. A rotary type heat exchange apparatus with automatic flowrate exchange modulation as claimed in claim 1, wherein said double flowcircuit fluid pumping device (123) constituted by two unidirectionalfluid pumps (120 a)(120 b) is configured for pumping gaseous or liquidstate fluids, wherein the two unidirectional fluid pumps (120 a)(120 b)constituting the double flow circuit fluid pumping device (123) exceptfor being driven by individually installed electric motors or by acommon electric motor, they can also be driven by engine power, or themechanical or electric power converted from other wind power, thermalenergy, temperature-difference energy, or solar energy.
 18. A rotarytype heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 1, wherein the operative control device(250) is equipped with the electric motor, engine power, or mechanicalor electric power generated or converted from other wind power, thermalenergy, temperature-difference energy, or solar energy for drivingvarious unidirectional fluid pumps (120 a)(120 b), or the rotating diskrotationally driving device (110), or capable of operatively controllingthe operating timing of the fluid pumps or fluid valves thereby changingthe flow directions of the two fluid streams passing through the rotarytype heat exchange rotating disk (100), or capable of operativelycontrolling the rotating speed of the rotary type heat exchange rotatingdisk (100) or the rotary type total heat exchange rotating disk (200)driven by the rotating disk rotationally driving device (110) to furtheroperatively control partial or all modulating functions of the rotatingspeed, flow rate, fluid pressure of the fluid pumps.
 19. A rotary typeheat exchange apparatus with automatic flow rate exchange modulation asclaimed in claim 1, wherein it is further through the operative controldevice (250) to operatively control the flow rate of the pumping fluidpumped by the double flow circuit fluid pumping device (123) and/or tooperatively control the rotating speed of the rotary type heat exchangerotating disk (100) or the rotary type total heat exchange rotating disk(200) driven by the rotating disk rotationally driving device (110),wherein the operating modes include one or more than one of thefollowing: 1) The adjustment or setting is manually operativelycontrolled; 2) The operative control is referring to the signal detectedby at least one installed temperature detecting device; 3) The operativecontrol is referring to the signal detected by at least one installedhumidity detecting device; 4) The operative control is referring to thesignal detected by at least one installed gaseous or liquid state fluidcomposition detecting device; 5) The operative control is performed bycombining the two or more than two methods of items 1)˜4).
 20. A rotarytype heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 1, wherein in setting up the flow rateoperative control function, the fluid flow rate operative control rangeincluding the stepped or stepless fluid flow rate modulations from ceaseof transportation to maximum transportation rate is relied on one ormore than one of the following devices to change the fluid flow rate,wherein it includes: 1) It is through operatively controlling thepumping rotating speed of the double flow circuit fluid pumping device(123) comprising two unidirectional fluid pumps (120 a)(120 b) withinthe range from cease of transportation to maximum transportation rate tofurther operatively control the fluid flow rate; 2) It is throughadopting the double flow circuit fluid pumping device (123) beinginstalled with operatively controllable fluid inlet/outlet valves tooperatively control the opening of the fluid inlet/outlet valves of thedouble flow circuit fluid pumping device (123) to further operativelycontrol the fluid flow rate; 3) It is through operatively controllingany one device of items 1)˜2) to pump the fluid intermittently so as tomodulate the average flow rate by the time ratio of pumping on/off. 21.A rotary type heat exchange apparatus with automatic flow rate exchangemodulation as claimed in claim 1, wherein the flow rate ratio betweenthe two fluid streams for passing through the rotary type heat exchangeapparatus (1000) during operation include one or more than one ratiomode of the following: 1) The flow rate of fluid in one flow circuit isgreater than the one in the other flow circuit; 2) The flow rates of thefluids in both flow circuits are the same; 3) Two fluid pumps indifferent pumping flow directions are alternatively operated toalternatively pump the two fluid streams in opposite flow directions.22. A rotary type heat exchange apparatus with automatic flow rateexchange modulation as claimed in claim 1, wherein beside of theoperating function of pumping fluids of the double flow circuit indifferent flow directions, the double flow circuit fluid pumping device(123) being constituted by two fluid pumps capable of bidirectionalpumping is through operatively controlling the pumping flow directionsof the two fluid streams to further have one or more than one specialoperating modes of the following: 1) Operatively controlling the fluidsin two flow circuits to be pumped in the same flow directions forpumping in fluids; 2) Operatively controlling the fluids in two flowcircuits to be reversely pumped in the same flow directions fordischarging fluids; 3) Operatively controlling the fluids in two flowcircuits to be periodically pumped in positive and reverse flowdirections for pumping in fluids in the same flow directions anddischarging fluids in reverse flow directions.